Biotechnology News

Mimicking living cells: Synthesizing ribosomes

(Nanowerk News) Synthetic biology researchers at Northwestern University, working with partners at Harvard Medical School, have for the first time synthesized ribosomes – cell structures responsible for generating all proteins and enzymes in our bodies – from scratch in a test tube.

Others have previously tried to synthesize ribosomes from their constituent parts, but the efforts have yielded poorly functional ribosomes under conditions that do not replicate the environment of a living cell. In addition, attempts to combine ribosome synthesis and assembly in a single process have failed for decades.

Michael C. Jewett, a synthetic biologist at Northwestern, George M. Church, a geneticist at Harvard Medical School, and colleagues recently took another approach: they mimicked the natural synthesis of a ribosome, allowing natural enzymes of a cell to help facilitate the man-made construction.

The technology could lead to the discovery of new antibiotics targeting ribosome assembly; an advanced understanding of how ribosomes form and function; and the creation of tailor-made ribosomes to produce new proteins with exotic functions that would be difficult, if not impossible, to make in living organisms.

“We can mimic nature and create ribosomes the way nature has evolved to do it, where all the processes are co-activated at the same time,” said Jewett, who led the research along with Church. “Our approach is a one-pot synthesis scheme in which we toss genes encoding ribosomal RNA, natural ribosomal proteins, and additional enzymes of an E. coli cell together in a test tube, and this leads to the construction of a ribosome.”

Jewett is an assistant professor of chemical and biological engineering at Northwestern’s McCormick School of Engineering and Applied Science.

The in vitro construction of ribosomes, as demonstrated in this study, is of great interest to the synthetic biology field, which seeks to transform the ability to engineer new or novel life forms and biocatalytic ensembles for useful purposes.

Comprising 57 parts — three strands of ribonucleic acid (RNA) and 54 proteins — ribosomes carry out the translation of messenger RNA into proteins, a core process of the cell. The thousands of proteins per cell, in turn, carry out a vast array of functions, from digestion to the creation of antibodies. Cells require ribosomes to live.

Jewett likens a ribosome to a chef. The ribosome takes the recipe, encoded in DNA, and makes the meal, or a protein. “We want to make brand new chefs, or ribosomes,” Jewett said. “Then we can alter ribosomes to do new things for us.”

“The ability to make ribosomes in vitro in a process that mimics the way biology does it opens new avenues for the study of ribosome synthesis and assembly, enabling us to better understand and possibly control the translation process,” he said. “Our technology also may enable us in the future to rapidly engineer modified ribosomes with new behaviors and functions, a potentially significant advance for the synthetic biology field.”

The synthesis process developed by Jewett and Church — termed “integrated synthesis, assembly and translation” (iSAT) technology — mimics nature by enabling ribosome synthesis, assembly, and function in a single reaction and in the same compartment.

Working with E. coli cells, the researchers combined natural ribosomal proteins with synthetically made ribosomal RNA, which self-assembled in vitro to create semi-synthetic, functional ribosomes.

They confirmed the ribosomes were active by assessing their ability to carry out translation of luciferase, the protein responsible for allowing a firefly to glow. The researchers then showed the ability of iSAT to make a modified ribosome with a point mutation that mediates resistance to the antibiotic clindamycin.

The researchers next want to synthesize all 57 ribosome parts, including the 54 proteins.

“I’m really excited about where we are,” Jewett said. “This study is an important step along the way to synthesizing a complete ribosome. We will continue to push this work forward.”